TWI496083B - Operating method for dual operating system, portable device and docking system - Google Patents

Description

Dual operating system operation method, portable electronic device and docking expansion Charging system

The present invention relates to an operating method of an operating system, and more particularly to a method of operating a dual operating system, a portable electronic device and a docking expansion system to which the operating method is applied.

In order to cope with the busy life rhythm of modern people, various electronic devices that do not occupy space and are convenient to carry are also innovated. Take the smart phone as an example. It not only has the functions of the traditional communication device, but also allows users to write files, send and receive emails, browse the Internet, or use the built-in operating system. Instant messaging software and other purposes. In other words, such a handheld communication device can be used not only to make calls, but also to provide a variety of functions like a small personal computer, and with the advancement of wireless network technology, the use of these functions is no longer subject to time and Space constraints, for modern people who are efficient in everything, have become one of the indispensable tools in life.

The portable electronic device described above generally employs a mobile operating system to perform various tasks. Compared to general computer operating systems used in notebook computers, desktop computers, or terminal devices, the functions of the mobile operating system cannot achieve the versatility of the general computer operating system. For example, Windows operating systems such as Windows XP or Windows VISTA can handle more complex tasks, including document editing, image processing, etc., and have higher performance than mobile operating systems. Therefore, in order to be able to improve The performance of the portable electronic device, the prior art proposes a docking expansion system with a dual operating system architecture, which can integrate the mobility of the mobile operating system and the functionality of the general computer operating system. However, when operating the dual operating system, when switching from one operating system to another, it takes a lot of time to wait for the portable electronic device to terminate the currently executing operating system, to reboot, and to switch to another operating system. . Such a process is not only a waste of time, but also is not convenient for the user to switch between the two operating systems.

The present invention provides a method for operating a dual-operating system that can be quickly switched between two operating systems when the portable electronic device is docked or removed from the docking station.

The present invention provides a portable electronic device that can be quickly switched between two operating systems.

The present invention provides a docking expansion system that enables a portable electronic device docked on a docking station to quickly switch between two operating systems.

The present invention provides a method for operating a dual operation system for switching between a first operating system and a second operating system on a one-way expansion system consisting of a portable electronic device and a docking station. The second operating system is divided into a first portion and a second portion, the portable electronic device stores the first portion of the first operating system and the second operating system, and the docking station stores the The second part of the second operating system. The method includes: when the portable electronic device executes the first operating system, and the first operating system is in normal operation, the portable electronic device can automatically start The first portion of the second operating system is moved and the operating screen of the first operating system is restored after completing the second portion of the second operating system. When the portable electronic device and the docking station are coupled to each other, and the portable electronic device executes the second operating system, the portable electronic device can automatically start the first job when the second operating system is in normal operation. The system replies to the operation screen of the second operating system after completing the startup procedure of the first operating system.

The present invention further provides a portable electronic device that can be coupled to an expansion base. The portable electronic device includes: a storage medium, a processor, and a connection controller. The storage medium stores a first operating system and a first portion of a second operating system, and the second operating system is divided into the first portion and a second portion stored in the docking station. When the processor executes the first operating system, and the first operating system is in an idle state for more than a time preset value, the processor automatically starts the first portion of the second operating system and executes the second system After the first part, the operation picture of the first operating system is restored. When the portable electronic device is coupled to a docking station, the processor executes the first portion of the storage medium and the second operating system stored in the second portion of the docking station. And when the idle state of the second operating system exceeds the time preset value, the processor automatically starts the first operating system, and returns to the operating screen of the second operating system after completing the startup process of the first operating system. The connection controller is configured to detect the connection state of the portable electronic device and the docking station

The invention further provides a docking expansion system, comprising: a portable electronic device and an expansion base. Where the portable electronic device includes storage a first operating system, and a first storage medium, a connection controller, and a processor of the first portion of the second operating system. The docking station is coupled to the portable electronic device, wherein the docking station includes a second storage medium storing a second portion of the second operating system, and the second operating system is coupled to the first portion The second part is composed. When the processor executes the first operating system, and the first operating system is in an idle state for more than a time preset value, the processor automatically starts the first part of the second operating system, and completes the second doing After the first part of the system, the operation screen of the first operating system is restored. When the processor executes the first portion stored in the first portion of the storage medium and the second portion stored in the second portion of the docking station, and the second operating system is in an idle state for more than one time When the value is set, the processor automatically starts the first operating system and returns to the idle state of the operating screen of the second operating system after completing the startup program of the first operating system.

In an embodiment of the present invention, the operating method of the dual operating system, the portable electronic device and the docking expansion system, wherein a file size of the first operating system is smaller than a file size of the second operating system.

In an embodiment of the present invention, the operating method of the dual operating system, the portable electronic device and the docking expansion system, wherein the first portion of the second operating system includes an operating system for starting the second operating system Start the required core code.

In an embodiment of the invention, the dual operating system operating method, the portable electronic device and the docking expansion system, wherein the second portion of the second operating system includes an application activation code.

In an embodiment of the present invention, the operating method of the dual operating system, the portable electronic device and the docking expansion system, wherein when the portable electronic device executes the first operating system and the first operating system is normal The step of automatically starting the first part of the second operating system in operation further comprises: restarting the portable electronic device. Loading the first portion of the second operating system. Executing the first portion of the second operating system.

In an embodiment of the present invention, the operating method of the dual operating system, the portable electronic device and the docking expansion system, wherein the portable operating device executes the second operating system comprises: loading and executing the portable The first portion of the second operating system stored in the electronic device and the second portion of the second operating system stored in the docking station.

In an embodiment of the present invention, the operating method of the dual operating system, the portable electronic device and the docking expansion system, wherein when the portable electronic device executes the second operating system and is in the second operating system The step of automatically starting the first operating system under normal operation further includes: restarting the portable electronic device. Load the first operating system. Execute the first operating system.

In an embodiment of the present invention, the operating method of the dual operating system, the portable electronic device and the docking expansion system, wherein the docking station further comprises an input module.

Based on the above, in the present invention, when the portable electronic device executes an operating system and the idle state is longer than the time preset value during the normal operation of the operating system, when the idle state is used, no important application is operated. The portable electronic device automatically starts another operating system, thinking that The subsequent dual-operation system is pre-prepared when switching (for example, initially starting and executing part of the second operating system or completely starting the first operating system). Therefore, when the user switches the portable electronic device from the operating system to another operating system, the time for starting another operating system can be greatly reduced to achieve the purpose of quickly switching between the two operating systems.

The above described features and advantages of the present invention will be more apparent from the following description.

In the present invention, a switching between a first operating system and a second operating system is performed on a docking system composed of a portable electronic device and a docking station. The portable electronic device is, for example, a personal digital assistant (PDA) or a mobile phone.

The first operating system is, for example, an operating system suitable for portable electronic devices, including Microsoft Corporation's Windows Mobile operating system (Windows Mobile), Apple Computer's iOS operating system, Google's Android operating system, and others. An operating system on a portable electronic device. The second operating system is, for example, a large-scale computer device suitable for a notebook computer, a home computer, or a terminal device. That is, a file size of the first operating system is smaller than a file size of the second operating system.

The second operating system can be divided into a first part and a second part. In an embodiment, the second operating system can be started in two stages. Therefore, the portable electronic device stores the first operating system and the second operating system The first part, and the docking station stores the second part of the second operating system. In an embodiment, the first portion of the second operating system includes an operating system boot required core code required to activate the second operating system. For example, the above operating system starts the necessary core code, including the core code that must be executed in the kernel initiation phase when the Microsoft Windows operating system is started. In still another embodiment, the second portion of the second operating system includes an application startup code, such as a program executed when the login phase (Logon phase) after the core initialization phase is completed when the Microsoft Windows operating system is started. code.

FIG. 1 is a schematic flow chart of an operation method of a dual operation system according to an embodiment of the invention. First, the state of the portable electronic device is determined. Referring to FIG. 1, in step S101, when the portable electronic device executes the first operating system, then in step S105, the portable operating device is determined to be portable under the normal operation of the first operating system. Whether the time that the first operating system executed on the electronic device is in an idle state is greater than a time preset value. The idle state is a state in which the processor usage rate when the portable electronic device executes the first operating system is lower than a set value. The above-described processor usage setting value is, for example, 5% to 50% and the time preset value is, for example, 10 to 20 minutes, but does not limit the scope of the present invention. In another embodiment, the time preset value may be an idle time upper limit value set by the user.

In step S111, when the time when the first operating system executed on the portable electronic device is in the idle state is greater than a preset value, the portable electronic device automatically starts the first portion of the second operating system. Then, in step S115, after the first part of the second operating system is started, Reply to the operation screen of the first operating system. On the other hand, when it is determined in step S105 that the time when the first operating system executed on the portable electronic device is in the idle state is not greater than a preset value, the display module of the portable electronic device displays the first The operation screen of the work system (step S125) is, for example, a desktop screen of the first work system.

In addition, in an embodiment, the step of automatically starting the first part of the second operating system by the portable electronic device is as follows. FIG. 2 is a schematic flow diagram of automatically executing a first operating system in a portable electronic device and automatically turning on a second operating system in a normal operation of the first operating system according to an embodiment of the invention. Referring to FIG. 2, in step S201, the portable electronic device is restarted. Thereafter, in step S205, the first portion of the second operating system is loaded. The first portion of the second operating system is loaded, for example, by loading the second operating system into the memory of the portable electronic device. Then, in step S211, the first part of the second operating system is executed. The first portion of the second operating system is executed, for example, by the processor executing a first portion of the second operating system to initially initiate and execute the second operating system.

Furthermore, in another embodiment, the portable electronic device executes the first operating system, and determines whether the time when the first operating system executed on the portable electronic device is in an idle state is greater than a preset value. Step 101 and step S105 are performed, for example, in a state where the portable electronic device is coupled to the docking station. Of course, in another embodiment, the portable electronic device executes the first operating system, and determines whether the time that the first operating system executed on the portable electronic device is in an idle state is greater than a time preset value. 101 and step S105 can also be in portable power The sub-device is not coupled to the docking station. That is, whether the portable electronic device is coupled to the docking station, when the portable electronic device executes the first operating system and the first operating system executed on the portable electronic device is in an idle state for more than one time. When the value is set, the portable electronic device automatically starts the first part of the second operating system. In other words, when the portable electronic device uses the portable electronic device or the portable electronic device has a low loading, the portable electronic device automatically starts the second operating system. In part, the second operating system is initially implemented, so that the subsequent user needs to couple the portable electronic device to the docking station (or has been coupled to the docking station), and switch from the first operating system to the second. In the operating system, the second part of the second operating system stored in the docking station can be directly activated to save time in starting the second operating system. The portable electronic device further has a connection controller for detecting whether the portable electronic device is coupled with the docking station to determine whether the portable electronic device can execute the complete second operating system. In addition, in the environment where the portable electronic device and the docking station are coupled to each other, and the portable electronic device executes the second operating system, the method of starting the first operating system is further performed in the following paragraphs. instruction of. FIG. 3 is a schematic flow chart of an operation method of a dual operation system according to an embodiment of the invention. Referring to FIG. 3, in an environment in which the portable electronic device and the docking station are coupled to each other, in step S301, the portable electronic device executes the second operating system. The second operating system is executed in the above step. For example, when the portable electronic device is powered on, the user or the system automatically selects to execute the second operating system, and the portable electronic device automatically loads and executes. The first portion of the second operating system stored by the portable electronic device and the second portion of the second operating system stored in the docking station, that is, the complete second operating system is executed. In step S305, it is determined whether the time that the second operating system executed on the portable electronic device is in an idle state is greater than a time preset value under normal operation of the second operating system. The idle state is a state in which the processor usage rate when the portable electronic device executes the second operating system is lower than a set value. The above-described processor usage setting value is, for example, 5% to 50% and the time preset value is, for example, 10 to 20 minutes, but does not limit the scope of the present invention. In another embodiment, the time preset value may be an idle time upper limit value set by the user.

In step S311, when the second operating system executed on the portable electronic device is in the idle state for more than a time preset value, the portable electronic device automatically starts the first operating system. Then, in step S315, the operation screen of the second operating system is restored after the first operating system is started. On the other hand, when it is determined in step S305, the portable electronic device determines whether the time when the second operating system executed on the portable electronic device is in an idle state is greater than a time preset value under normal operation of the second operating system. The result shows that the display module of the portable electronic device displays the operation screen of the second operating system when the time when the second operating system executed on the portable electronic device is in the idle state is not greater than a preset value. (Step S325), for example, is a desktop screen of the second operating system.

In addition, in an embodiment, the step of automatically starting the first operating system by the portable electronic device is as follows. FIG. 4 illustrates a second operating system being executed on a portable electronic device and automatically turned on according to an embodiment of the invention. A schematic diagram of the flow of the first operating system. Referring to FIG. 4, in step S401, the portable electronic device is rebooted. Thereafter, in step S405, the first operating system is loaded. The first operating system is loaded, for example, the first operating system is loaded into the memory of the portable electronic device. Next, in step S411, the first operating system is executed. The first operating system is executed, for example, by executing a first operating system with a processor to start and execute the first operating system.

It is worth noting that the portable electronic device coupled to the docking station is not operated by the user or the load of the portable electronic device is low, so that the portable electronic device automatically starts and executes the first operating system. Therefore, when the subsequent user wants to remove the portable electronic device from the docking station, the second operating system can be directly switched to the first operating system to save time for starting the first operating system.

In the above embodiments, the portable electronic device is executing an operating system and the portable electronic device automatically starts another operating system during normal operation, so as to save another operation when the operating system is subsequently switched. The time of the system. However, the invention is not limited thereto. In another embodiment, when the power of the portable electronic device is activated to perform the booting process of the portable electronic device, it is determined by the connector whether the portable electronic device is coupled to the docking station. When the portable electronic device is coupled to the docking station, the display module of the portable electronic device displays a menu of operating systems, including options for representing the first operating system and the second operating system, respectively, for the user to select. Is to execute the first operating system or the second operating system. When the user chooses to execute the first operating system, the docking station is viewed as It is an external storage device of the portable electronic device. In another embodiment, when the user couples the portable electronic device that has been turned on and executes the first operating system to the docking device, the connection signal generated by the connector of the portable electronic device can be The processor of the portable electronic device automatically displays the operating system menu on the display module for the user to select whether to reboot to switch from the first operating system (the operating system suitable for the portable electronic device) to the second operation System (applicable to the operating system of large computer devices such as notebook computers, home computers, and terminal devices).

Please refer to FIG. 5, which illustrates a docking expansion system in accordance with the present invention. The docking expansion system of the embodiment includes a portable electronic device 502 and a docking station 504. The portable electronic device 502 includes a first storage medium 502a and a processor 502b. The first storage medium 502a stores a first operating system and a first portion of a second operating system. The processor is, for example, a central processing unit of the X86 architecture. The portable electronic device 502 further includes a display module 502c and a connector 502d. The portable electronic device further has a connection controller for detecting whether the portable electronic device is coupled with the docking station to determine whether the portable electronic device can execute the complete second operating system.

The docking station 504 includes a second storage medium 504a. The second storage medium 504a stores a second portion of the second operating system. The docking station 504 further includes a connector 504b, an input module 504c and a CD player 504d. The input module 504c can receive input signals from a physical keyboard, a virtual keyboard, a touch device, or a mouse device, for example. The docking station 504 is coupled to the connector 502d of the portable electronic device via the connector 504b. That is, when the portable electronic device 502 is coupled to the docking station 504 to form a docking expansion system, and the portable electronic device 502 executes an operating system suitable for a large computer device such as a notebook computer, a home computer, or a terminal device (second In the case of the operating system, the docking expansion system can be regarded as a large-scale computer device such as a notebook computer, a home computer, or a terminal device, and can provide a relatively diverse application software, and can perform relatively complicated operations and operations. Depending on the product design, the portable electronic device and the docking station can also be connected to each other by means of wireless signals and transmit instructions and data without necessarily relying on a physical connector. The wireless signal used can be Bluetooth, infrared, or Wireless Lan signal.

When the processor 502b of the portable electronic device 502 executes the first operating system (such as the above step S101), and the time when the first operating system is in the idle state is greater than the time preset value (such as the above step S105), the processor 502b The first part of the second operating system is automatically started (as in step S111 above), and the operation screen of the first operating system is restored (as in step S115 above). The processor 502b automatically starts the first part of the second operating system (such as the above step S111) and further includes the related technical content presented in steps S201 to S211 of the embodiment shown in FIG. 2. Since the above steps are all detailed in the foregoing embodiments, they are not described herein.

In addition, when the processor 502b executes a complete second operating system stored in the first portion of the first storage medium 502a and the second portion of the second storage medium 504a stored in the docking station (step S301 above), and When the time when the second operating system is in the idle state is greater than the time preset value (as in step S305 above), the processor 502b automatically starts the first operating system (as described above). Step S311), and return to the operation screen of the second operating system (step S315 described above). The processor 502b automatically starts the first operating system (such as the above step S311) and further includes related technical content presented in steps S401 to S411 of the embodiment shown in FIG. Since the above steps are all detailed in the foregoing embodiments, they are not described herein.

In summary, in the present invention, when the portable electronic device executes an operating system and the idle state is greater than the time preset value during the normal operation of the operating system, the state in which the important application is not operated when the idle state is utilized Next, the portable electronic device automatically starts another operating system to prepare in advance for the subsequent dual operating system switching (for example, initially starting and executing part of the second operating system or completely starting the first operating system). Therefore, when the user switches the portable electronic device from the operating system to another operating system, the time for starting another operating system can be greatly reduced to achieve the purpose of quickly switching between the two operating systems.

Although the present invention has been disclosed in the above embodiments, it is not intended to limit the invention, and any one of ordinary skill in the art can make some modifications and refinements without departing from the spirit and scope of the invention. The scope of the invention is defined by the scope of the appended claims.

S101~S125, S201~S211, S301~S325, S401~S411‧‧‧ method step flow

502‧‧‧Portable electronic device

502a‧‧‧First storage media

502b‧‧‧ processor

502c‧‧‧ display module

502d‧‧‧Connector

504‧‧‧Expansion base

504a‧‧‧Second storage media

504b‧‧‧Connector

504c‧‧‧ input module

504d‧‧‧CD player

FIG. 1 is a schematic flow chart of an operation method of a dual operation system according to an embodiment of the invention.

FIG. 2 illustrates an automatic operation when the portable electronic device executes the first operating system and enters the idle state of the first operating system according to an embodiment of the invention. Open the process diagram of the second operating system.

FIG. 3 is a schematic flow chart of an operation method of a dual operation system according to an embodiment of the invention.

FIG. 4 is a schematic flow diagram of automatically turning on the first operating system when the portable electronic device executes the second operating system and enters the idle state of the second operating system according to an embodiment of the invention.

FIG. 5 illustrates a docking expansion system in accordance with an embodiment of the present invention.

S101~S125‧‧‧ method step flow

Claims (20)

A method for operating a dual operation system for switching between a first operating system and a second operating system on a one-way expansion system comprising a portable electronic device and a docking station, wherein the second The operating system is divided into a first portion and a second portion, the portable electronic device stores the first portion of the first operating system and the second operating system, and the docking station stores the second operating system The second part of the method includes: the portable electronic device determining a state of the portable electronic device; and when the portable electronic device executes the first operating system, and entering a first operating system After the idle state, the portable electronic device automatically starts the first part of the second operating system, and after the portable electronic device starts the first part of the second operating system, replies to the first An operation screen of an operating system; when the portable electronic device is coupled to the docking station, the portable electronic device executes the first portion and the second portion of the second operating system, and enters the First After the idle state of the operating system, the portable electronic device automatically starts the first operating system, and when the portable electronic device starts the first operating system, returns a working picture of the second operating system; And when the portable electronic device is not coupled to the docking station, the portable electronic device executes the first operating system. The operating method of the dual operating system according to claim 1, wherein a file size of the first operating system is smaller than a file size of the second operating system. The operating method of the dual operating system of claim 1, wherein the first portion of the second operating system includes an operating system startup essential core code for initiating the second operating system. The operating method of the dual operating system of claim 1, wherein the second portion of the second operating system comprises an application activation code. The operating method of the dual operating system of claim 1, wherein the portable electronic device executes the first operating system and the first operating system is in the idle state of the first operating system for more than The portable electronic device automatically activates the first portion of the second operating system when the time is preset. The operating method of the dual operating system according to claim 5, wherein the idle state of the first operating system is that the portable electronic device executes the first operating system with a processor usage lower than a setting. The status of the value. The operating method of the dual operating system of claim 1, wherein the portable electronic device automatically starts the second after executing the first operating system and entering the idle state of the first operating system The first part of the operating system further includes: restarting the portable electronic device; loading the first portion of the second operating system; and executing the first portion of the second operating system. The operating method of the dual operating system of claim 1, wherein the portable electronic device executing the second operating system comprises: Loading and executing the first portion of the second operating system stored in the portable electronic device and the second portion of the second operating system stored in the docking station. The operating method of the dual operating system of claim 1, wherein the portable electronic device automatically starts the first when the second operating system is powered on and enters the idle state of the second operating system. The step of operating the system further includes: restarting the portable electronic device; loading the first operating system; and executing the first operating system. The operating method of the dual operating system of claim 1, wherein the portable electronic device executes the second operating system and the second operating system is in the idle state of the second operating system for more than When the preset value is used for a time, the portable electronic device automatically starts the first operating system. The operating method of the dual operating system according to claim 10, wherein the idle state of the second operating system is that the portable electronic device executes the second operating system, and the processor usage rate is lower than a setting. The state at the time of the value. A docking expansion system includes: a portable electronic device, wherein the portable electronic device includes a first storage medium storing a first operating system and a first portion of a second operating system, and a connection control And a processor, wherein when the processor executes the first operating system, and the portable electronic device enters the After an idle state of an operating system, the processor automatically starts the first portion of the second operating system, and after the portable electronic device starts the first portion of the second operating system, replies An operation screen of the first operating system; and a docking station coupled to the portable electronic device, wherein the docking station includes a second storage medium for storing a second portion of the second operating system, And the second operating system is composed of the first part and the second part, wherein the connection controller is configured to detect a connection state of the portable electronic device and the docking station, wherein when the connection controller detects When the portable electronic device is coupled to the docking station, the processor executes the first portion and the second portion of the second operating system, and the portable electronic device enters the second operating system After the idle state, the processor automatically starts the first operating system, and when the portable electronic device starts the first operating system, returns a working picture of the second operating system; and when the connection Detecting the braking device when the portable electronic device is not coupled to each other, the processor automatically starts the first operating system and the docking station. The docking expansion system of claim 12, wherein a file size of the first operating system is smaller than a file size of the second operating system. The docking expansion system of claim 12, wherein the first portion of the second operating system comprises an operating system startup essential core code for initiating the second operating system. Such as the docking expansion system described in claim 12, The second portion of the second operating system includes an application launch code. The docking expansion system of claim 12, wherein the processor executes the first operating system, and determines that the idle state of the first operating system exceeds a time preset value, wherein the first job The idle state of the system is a state when the processor usage rate of the portable operating device when the first operating system is lower than a set value. The docking expansion system of claim 12, wherein the processor executes the second operating system, and determines that the idle state of the second operating system exceeds a time preset value, wherein the second job The idle state of the system is a state in which the processor usage rate when the portable electronic device executes the second operating system is lower than a set value. The docking expansion system of claim 12, wherein the state of the portable electronic device is that the processor executes the first operating system and the idle state of the first operating system exceeds a time When the preset value is reached, the processor automatically starts the first part of the second operating system and returns to the operation screen of the first operating system. The docking expansion system of claim 12, wherein when the portable electronic device is coupled to the docking station, the processor is configured to be stored in the storage medium. The processor automatically starts when the first portion is complete with the second operating system stored in the second portion of the docking station, and the idle state of the second operating system exceeds a predetermined time. The first operating system returns to the operation screen of the second operating system. Such as the docking expansion system described in claim 12, The docking station further includes an input module.